Improving tubular protonic ceramic fuel cell performance by compensating Ba evaporation via a Ba-excess optimized proton conducting electrolyte synthesis strategy

Kim, You-Dong; Kim, In-Ho; Meisel, Charlie; Herradón, Carolina; Rand, Peter W; Yang, Jayoon; Kim, Hyun Sik; Sullivan, Neal P; O’Hayre, Ryan

doi:10.1088/2515-7655/ad5760

J. Phys. Energy

2024

DOI: 10.1088/2515-7655/ad5760

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Improving tubular protonic ceramic fuel cell performance by compensating Ba evaporation via a Ba-excess optimized proton conducting electrolyte synthesis strategy

You-Dong Kim,

In-Ho Kim,

Charlie Meisel

et al.

Abstract: Protonic ceramic fuel cells (PCFCs) are emerging as a promising technology for reduced temperature ceramic energy conversion devices. The BaCe0.4Zr0.4Y0.1Yb0.1O3−δ (BCZYYb4411) electrolyte is notable for its high proton conductivity. However, the tendency of barium to volatilize in BCZYYb4411 during high-temperature sintering compromises its chemical stability and performance. This study investigates the effects of intentionally incorporating excess barium into BCZYYb4411, formulated as Ba1+… Show more

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Cited by 3 publications

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TiO2 containing glass sealant for protonic ceramic fuel cell applications: Microstructure, strength and stability studied in sealing of BaZr0.1Ce0.7Y0.1Yb0.1O3-δ electrolyte to Crofer 22H interconnect

Gao,

Si,

Yang

et al. 2024

Ceramics International

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TiO2 containing glass sealant for protonic ceramic fuel cell applications: Microstructure, strength and stability studied in sealing of BaZr0.1Ce0.7Y0.1Yb0.1O3-δ electrolyte to Crofer 22H interconnect

Gao,

Si,

Yang

et al. 2024

Ceramics International

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Technological achievements in the fabrication of tubular-designed protonic ceramic electrochemical cells

Gordeeva,

Tarutin,

Danilov

et al. 2024

Mater. Futures

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Protonic ceramic electrochemical cells provide an excellent basis for the advancement of high-temperature solid oxide devices, offering potential solutions to a range of challenges in the hydrogen energy and carbon capture fields. The facilitated ionic transport in proton-conducting electrolytes enables these cells to operate at temperatures 100 °C–500 °C lower than those of conventional solid oxide cells with known zirconia electrolytes. As a result, promising performances have been reported for various types of proton ceramic electrochemical cells. Nevertheless, these advancements have been demonstrated only at the laboratory scale, whereas their ZrO2-based counterparts have already been commercialized. This review presents an overview of the fundamental and applied aspects related to the fabrication of tubular protonic ceramic electrochemical cells and their subsequent characterization as hydrogen permeation membranes, hydrogen pumps, hydrogen sensors, fuel cells, electrolysis cells, and electrochemical reactors. A specific focus is placed on the technological aspects of the tube preparations derived from the original powder sources as well as the dimensional characteristics of the tubes, which serve as an indicator of scaling. Therefore, this review serves as a starting point for the development and scaling of protonic ceramic electrochemical cells, with the potential for large-scale production.

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Role of Sintering Aids in Electrical and Material Properties of Yttrium- and Cerium-Doped Barium Zirconate Electrolytes

Loganathan,

Biswas,

Kaur

et al. 2024

Processes

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Ceramic proton conductors have the potential to lower the operating temperature of solid oxide cells (SOCs) to the intermediate temperature range of 400–600 °C. This is attributed to their superior ionic conductivity compared to oxide ion conductors under these conditions. However, prominent proton-conducting materials, such as yttrium-doped barium cerates and zirconates with specified compositions like BaCe1−xYxO3−δ (BCY), BaZr1−xYxO3−δ (BZY), and Ba(Ce,Zr)1−yYyO3−δ (BCZY), face significant challenges in achieving dense electrolyte membranes. It is suggested that the incorporation of transition and alkali metal oxides as sintering additives can induce liquid phase sintering (LPS), offering an efficient method to facilitate the densification of these proton-conducting ceramics. However, current research underscores that incorporating these sintering additives may lead to adverse secondary effects on the ionic transport properties of these materials since the concentration and mobility of protonic defects in a perovskite are highly sensitive to symmetry change. Such a drop in ionic conductivity, specifically proton transference, can adversely affect the overall performance of cells. The extent of variation in the proton conductivity of the perovskite BCZY depends on the type and concentration of the sintering aid, the nature of the sintering aid precursors used, the incorporation technique, and the sintering profile. This review provides a synopsis of various potential sintering techniques, explores the influence of diverse sintering additives, and evaluates their effects on the densification, ionic transport, and electrochemical properties of BCZY. We also report the performance of most of these combinations in an actual test environment (fuel cell or electrolysis mode) and comparison with BCZY.

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Improving tubular protonic ceramic fuel cell performance by compensating Ba evaporation via a Ba-excess optimized proton conducting electrolyte synthesis strategy

Cited by 3 publications

References 38 publications

TiO2 containing glass sealant for protonic ceramic fuel cell applications: Microstructure, strength and stability studied in sealing of BaZr0.1Ce0.7Y0.1Yb0.1O3-δ electrolyte to Crofer 22H interconnect

TiO2 containing glass sealant for protonic ceramic fuel cell applications: Microstructure, strength and stability studied in sealing of BaZr0.1Ce0.7Y0.1Yb0.1O3-δ electrolyte to Crofer 22H interconnect

Technological achievements in the fabrication of tubular-designed protonic ceramic electrochemical cells

Role of Sintering Aids in Electrical and Material Properties of Yttrium- and Cerium-Doped Barium Zirconate Electrolytes

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